Global Journal of Engineering Sciences (GJES)
COVID-19
Herd Immunity Simulation with Scratch
Authored by Leyu Wang
Abstract
The
total infected population in the pandemic is found to be related to the number
of risky contacts a person may have per day. COVID-19 will infect the entire
population if the average person has one risky encounter per day. The virus is
unlikely to spread further if the average person has lower than 0.23 times
risky encounter per day. In this study, herd immunity for COVID-19 is simulated
with scratch. The vaccine was added later as a factor in the study.
Introduction
Herd
immunity is a concept that is frequently mentioned in COVID-19 pandemic. The
idea is that the population, which is exposed and immunized to the virus, will
serve as a barrier to prevent further spreading of the disease [1,2]. It is
important to know the percentages of total infected population before herd
immunity is achieved and the pandemic ends. Under certain conditions, the
naturally occurred herd immunity can only occur if everyone is infected with
the virus. Previous study of herd immunity assumes a static population, where
individual does not move from place to place in simulation [3-5]. The result
may underestimate the severity of COVID-19 pandemic.
Methodology
This
study analyzed 100 freely moved people in a square area using simulation. The
time scale of one second in simulation represents one day in real life. Each
person continuously moves to a random position in n-seconds time. A new random
position is given once the old one is reached. The time duration n can be
adjusted to represent different social activity level (larger n means less
social activity). This semi-random moving pattern is set to represent actual
behavior of people in a community. The simulation runs with 0 infected person
first to determine the daily risky contact per person. In real life, this means
how many times a person may have close contact to others that can potentially
transmit disease each day. Once the simulation starts, the patient zero turns
infectious (red) from healthy (blue). The virus is transmitting if the healthy
person (blue) touches the infectious person (red). The infected person enters
the latent period (yellow) of 6 days [6–8], where the person carries virus but
not infectious to others. After that, the infected person enters the infectious
period (red) of 9 days [9]. After the infectious period, the person gets
immunized (purple) and can no longer pass disease to others or get sick again.
The simulation continues until no more infectious person exists in the sandbox
(Figure 1). At the end of the simulation, the daily personal contact number,
“R” value for the first patient, percentage of total infected population, and
duration of pandemic are recorded. The “R” value refers to number of people
each patient can infect before the end of infectious period. We only recorded
the R value for patient zero as it changes with increasing immunized
population. Each simulation is repeated three times and their average value is
recorded in Table 1. The total infected population and the pandemic duration is
plotted against the daily risky contact per person
Result Interpretation and Discussion
The number of daily risky
contact per person is direct related to the total infectious population of the
pandemic. A lower daily contact number will allow a larger percentage of the
population not infected when pandemic ends. COVID-19 will infect everyone if
the average person in society has one times of risky contact per day. If the
average person has 0.23 times or less risky contact per day, the virus is more
likely to die down without further spreading to other people (Figure 2 Left).
The key point for Disease prevention and control measures is to reduce the
number of risky contacts among peoples. Mandatory mask-wearing and social
distancing makes each contact less risky and thus reduce the number of
effective risky contact. Remote learning, working from home and travel
restriction will directly reduce the numbers contacts.
The high contagious of
SARS-Cov-2 is due to three factors suggested by the simulation:
• The virus has long
incubation and infectious period.
• Most contagious person still
moves around in society due to asymptomatic infection or mild symptoms.
• The condition of risky
contact between two people is easily achieved as the disease is airborne
transmitted.
Vaccinated Result
The study of a vaccination program
is presented for comparison. The program is set to distribute the vaccine to
the entire population in 120 days. The distribution of the vaccine starts at
the same time of the patient zero get infectious. The vaccine program
represented by a syringe freely moves in the sandbox and gives the vaccine to
the person in contact (Figure 3). The moving speed is adjusted to reach
approximately 120 days of delivery time to the whole population. The result
suggests the vaccination program protect part of the population that are not
vaccinated only if the daily risky contact per person is below 1. If the value
is above 1, the vaccine only protects those who are vaccinated. All
unvaccinated person will be infected.
Acknowledgement
This work is dedicated to the
memorial of Dr. Runtao Yan for his guidance and mentorship. The idea is based
on a course project of the first author. Special thanks to MIT scratch program
and David Zhang for his teaching and support. Special thanks to Cing-Dao Kan
for his valuable suggestions. Source Code of the simulation program
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